U.S. patent application number 12/206631 was filed with the patent office on 2009-01-01 for headphone driver/charge pump combination.
Invention is credited to Tony Doy.
Application Number | 20090003618 12/206631 |
Document ID | / |
Family ID | 22007841 |
Filed Date | 2009-01-01 |
United States Patent
Application |
20090003618 |
Kind Code |
A1 |
Doy; Tony |
January 1, 2009 |
HEADPHONE DRIVER/CHARGE PUMP COMBINATION
Abstract
A headphone driver amplifier operative without an external
negative voltage power supply, coupled directly to the headphone
speakers without the need for DC coupling capacitors used for
preventing DC reaching the headphones. An onboard power supply
generates a negative voltage rail which powers the output
amplifiers, allowing driver amplifier operation from both positive
and negative rails. Since the amplifiers can be biased at ground
potential (O volts), no significant DC voltage exists across the
speaker load and the need for DC coupling capacitors is
eliminated.
Inventors: |
Doy; Tony; (Sunnyvale,
CA) |
Correspondence
Address: |
Perkins Cole LLP
P.O. Box 1208
SEATTLE
WA
98111-1208
US
|
Family ID: |
22007841 |
Appl. No.: |
12/206631 |
Filed: |
September 8, 2008 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
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10056994 |
Jan 24, 2002 |
7061327 |
|
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12206631 |
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Current U.S.
Class: |
381/74 ;
381/120 |
Current CPC
Class: |
H03F 3/005 20130101;
H03F 3/211 20130101; H04R 3/007 20130101 |
Class at
Publication: |
381/74 ;
381/120 |
International
Class: |
H04R 1/10 20060101
H04R001/10 |
Claims
1. An amplifier circuitry for directly driving stereo headphones,
said amplifier circuitry being driven by a single supply voltage
VDD, said amplifier circuitry comprising: a first amplifier and a
second amplifier, the first amplifier having an output coupled to a
first headphone with no output capacitor needed for DC blocking and
the second amplifier having an output coupled to a second headphone
with no output capacitor needed for DC blocking; and a charge pump
circuitry operable to provide a negative power supply substantially
equal in magnitude to a positive power supply.
2. A charge pump enabled stereo headphone system comprising the
following formed on a single integrated circuit: a positive power
supply with respect to ground originating external to said single
integrated circuit; a charge pump coupled to said positive power
supply and operable to provide, internal to said single integrated
circuit, a negative power supply with respect to ground
substantially equal in magnitude to a quanta of said positive power
supply; a first headphone amplifier powered by both said positive
power supply and said negative power supply, said first headphone
amplifier having a first audio input driven by a first audio signal
provided external to said single integrated circuit, and a first
audio output suitable for driving a stereo headphone with no output
capacitor needed for DC blocking; a second headphone amplifier
powered by both said positive power supply and said negative power
supply, said second headphone amplifier having a second audio input
driven by a second audio signal provided external to said single
integrated circuit; and a second audio output suitable for driving
said stereo headphone with no output capacitor needed for DC
blocking.
3. The charge pump enabled stereo headphone system as recited in
claim 2, wherein said first audio input is an audio in for a right
stereo headphone and said second audio input is an audio in for a
left stereo headphone.
4. The charge pump enabled stereo headphone system as recited in
claim 2, further comprising a click/pop suppression means coupled
to said first headphone amplifier and said second headphone
amplifier.
5. The charge pump enabled stereo headphone system as recited in
claim 2, further comprising a shutdown circuit.
6. An amplifier circuitry formed on a single integrated circuit for
directly driving stereo headphones, said amplifier circuitry
operating at both positive and negative voltage without requiring
an external negative voltage power supply, said amplifier circuitry
comprising: a first amplifier and a second amplifier, the first
amplifier having an output coupled to a first headphone with no
output capacitor needed for DC blocking and the second amplifier
having an output coupled to a second headphone with no output
capacitor needed for DC blocking; and a charge pump circuitry
operable to provide an internal negative power supply suitable for
providing a negative voltage for use with the first amplifier and
the second amplifier, the internal negative power supply
substantially equal in magnitude to a quanta of a positive power
supply coupled to the charge pump circuitry, wherein the positive
power supply may originate internally or externally with respect to
the amplifier circuitry.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] The present application is a continuation of U.S. patent
application Ser. No. 10/056,994, filed Jan. 24, 2002, issued Jun.
13, 2006, as U.S. Pat. No. 7,061,327. The present application
claims priority through co-pending U.S. patent application Ser. No.
11/711,480, filed Feb. 26, 2007, which is a continuation of U.S.
application Ser. No. 11/039,386, filed Jan. 18, 2005, which is a
continuation-in-part of U.S. patent application Ser. No.
10/056,994, filed Jan. 24, 2002, all of which are incorporated
herein by reference and to which priority is claimed.
FIELD OF THE INVENTION
[0002] This invention relates generally to amplifier circuits and
more particularly to headphone driver amplifier circuits operating
from a single positive voltage supply.
BACKGROUND OF THE INVENTION
[0003] Systems and devices using headphones are ubiquitous in many
fields of technology. The trend to miniaturize electronic devices
has resulted in the need for smaller headphone devices.
[0004] PRIOR ART FIG. 1A illustrates a typical headphone
connectivity diagram 8. The right headphone lead 12 and the left
headphone lead 14 couple to the right and left headphone speakers
respectively represented here by a headphone load 10 to the rest of
the system. Each headphone load 10 as well as the overall system is
connected to a common ground 16.
[0005] PRIOR ART FIG. 1B illustrates a prior art stereo headphones
system 11 using a 3-way "jack socket" design for connecting a pair
of headphones to a stereo system. As shown in FIG. 1B, the 3-way
jack-socket design 11 is made of three electrically isolated
portions 22, 26, and 28, dividers 24 and 29, and a body 23. The
design of the 3-way jack socket allows for the use of a single jack
socket 11 to connect a pair of headphones 18 and 20 via the leads
12 and 14 and the common ground lead 16. As illustrated herein
PRIOR ART FIG. 1A, the 3-way jack-socket system 11 includes the tip
22 which couples the left headphone speaker 18 to the stereo system
via the lead 12. Similarly, the middle portion 28 of the jack
socket 23 couples the right headphone speaker 20 to the stereo
system via the lead 14. A rear portion 26 of the jack socket 23
connects the common return for the left 18 and the right 20
headphones to a common ground 16 that may be connected to the
stereo system chassis to form a common ground. Dividers 24 and 29
electrically isolate from each other, the various electrically
charged portions 22, 26 and 28 of the 3-way jack-socket.
[0006] Each headphone may be represented by a resistive headphone
load to be driven by the incoming signals. Typical value for the
resistive load of a headphone speaker is in 16 to 32 .OMEGA.(ohm)
range.
[0007] PRIOR ART FIG. 2 illustrates a typical headphone driver
amplifier circuit 30. The headphone driver amplifier circuit 30
includes a pair of headphone amplifiers 32 and 34, a pair of DC
coupling capacitors 40 and 42, and a pair of outputs leads 12 and
14 connecting the headphone amplifiers to the headphone speakers
represented by the headphone load 10.
[0008] As shown in PRIOR ART FIG. 2, the incoming (driving) signals
are amplified before reaching each headphone. In the cases where
the headphones are used with portable electronic devices such as
portable cassette players or portable CD players, a single positive
power supply such as a battery is the only source of power. In a
typical portable device, headphone driver amplifiers are from a
single supply (e.g. a 5 volts or 3.3 volts battery). In order to
accurately reflect the incoming signals amplified by the headphone
amplifiers 32 and 34, the outputs of the headphone amplifiers 32
and 34 are biased at mid-rail (V.sub.DD/2) allowing for the
generation of both positive and negative going signals without
clipping. As a result, the output of the amplifiers 32 and 34 are
at a higher DC voltage with respect to ground. In order to prevent
high currents from flowing through the headphones and having the
headphones in a continuously on state, direct current (DC) coupling
capacitors such as 40 and 42 are inserted in series with the output
of the amplifiers 32 and 34, in order to prevent a DC current from
reaching the headphones. The DC coupling capacitors 40 and 42 act
as a high pass filter preventing DC and very low frequency signals
from reaching the headphones. In order to reproduce low frequency
input signals into the 16-32. OMEGA.(ohm) load of a typical
headphone, the value of these DC coupling capacitors needs to be in
the 100-470.mu.F (micro Farad) range. However, physical size of a
100-470.mu.F capacitor is prohibitively large and prevents
miniaturization of the headphone circuitry. The physical size and
cost of these DC blocking capacitors 40 and 42 is of a greater
importance in the design of portable equipment and therefore
implementing an amplifier topology that either completely
eliminates the DC blocking capacitors or reduces their value and
size is desirable.
[0009] Returning to PRIOR ART FIG. 2, the incoming signal I is
input to the two power amplifiers 32 and 34. In order to generate
positive and negative going incoming signals without signal
clipping, the amplifiers 32 and 34 are typically biased at mid-rail
(VDD/2), and thus the positive and negative power supply terminals
of the two amplifiers 32 and 34 are connected to the positive power
supply VDD and ground (VSS) respectively. As a result, the outputs
36 and 38 of the input amplifier 32 and 34 need to be coupled to
the left 18 and right 20 headphones through DC blocking capacitors
40 and 42 respectively. As previously discussed, in order to
reproduce low frequencies into the typical 16 to 32 ohm headphones,
the size of the DC blocking capacitors has to be in 100 to 470.mu.F
range. The physical dimensions for these internal capacitors is
very large and the size acts as a barrier to much desired
miniaturization of the headphone driver amplifier circuit 30.
[0010] PRIOR ART FIG. 3 illustrates one prior art solution
eliminating the need for DC coupling capacitors. A prior art driver
amplifier circuit 43 includes a pair of headphone amplifiers 32 and
34 directly coupled to a headphone load 10 through a pair of leads
36 and 38, and a third amplifier 44 connected to the headphone load
10 via the lead 16. The headphone load 10 (representing the
headphones 18 and 20) is biased between ground (GND) and the supply
voltage VDD. With both headphone amplifiers biased to approximately
the same DC value, very little DC current flows through the
headphones, and the third amplifier sinks or sources current as
necessary. Although the circuit depicted in PRIOR ART FIG. 3
eliminates the need for large DC coupling capacitors, this system
has the disadvantage of having a common return 16 that must now be
isolated from the equipment chassis since it has a DC voltage on
it. This isolation introduces additional problems such as possible
circuit damage if the electrical isolation of the common return
from the rest of the system fails.
[0011] Therefore, it is desirable to provide a circuit headphone
amplifier system that could operate from a single positive voltage
supply, and which does not require the usual large DC coupling
capacitors or need the physical isolation of the common return of
the headphones.
SUMMARY OF THE INVENTION
[0012] The system of the present invention, allows a headphone
driver amplifier to operate from a single voltage supply, yet does
not require the usual series coupling capacitors used for
preventing DC current from reaching the headphones. An on-board
power supply generates a negative voltage rail, which powers the
output amplifiers, allowing driver amplifier operation from both
positive and negative rails. In this way, the amplifier can be
biased at ground (0 volts) potential, generating no significant DC
voltage across the headphone load (the headphones speakers).
[0013] Briefly, one aspect of the present invention is embodied in
a circuit enabling a headphone driver amplifier to operate from a
single voltage supply comprising of an amplifier having an output
coupled to a headphone, the amplifier having a first and a second
power supply lead, the first power supply lead connected to a
positive supply voltage, and a DC voltage to voltage converter
having an output and a power source lead connected to the positive
voltage supply, the output of the charge pump circuitry connected
to the second power supply lead, and the charge pump generating an
output voltage at the output that is substantially equal in
magnitude to some quanta of the negative of the power supply
voltage.
BRIEF DESCRIPTION OF THE DRAWINGS
[0014] PRIOR ART FIG. 1A illustrates a typical headphone
connectivity diagram;
[0015] PRIOR ART FIG. 1B illustrates a prior art stereo headphones
design 11 using a 3-way "jack socket" design for connecting a pair
of headphones to a stereo system;
[0016] PRIOR ART FIG. 2 illustrates a typical prior art headphone
driver amplifier circuit;
[0017] PRIOR ART FIG. 3 illustrates one prior art solution
eliminating the need for DC coupling capacitors;
[0018] FIG. 4 illustrates a headphone amplifier circuit according
to the present invention;
[0019] FIG. 5 illustrates one embodiment of the headphone amplifier
system of the present invention in a circuit;
[0020] FIG. 6 is an illustration of an alternative embodiment of a
headphone amplifier system according to the present invention;
[0021] FIG. 7 is illustrates a simple capacitor based, IC charge
pump circuitry; and
[0022] FIG. 8 is illustrates a simple capacitor based discrete
charge pump circuitry.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0023] Prior art headphone driver systems for portable devices
operate off of a single power supply, requiring the biasing of the
headphones at mid-range of the power supply in order to fully
represent the incoming signal without the danger of any clipping.
As a result, these prior art systems require DC blocking capacitors
to be used in series with the amplifiers driving the headphones.
The value and physical size of these DC coupling capacitors are
prohibitively large and limit miniaturization highly desired in
most systems.
[0024] One aspect of the present invention allows for a headphone
driver/amplifier circuits to operate off of a single voltage
supply, without requiring the usual series coupling capacitors
necessary for preventing DC current from reaching the headphones An
on-board power supply generates a negative voltage rail, which
powers the output amplifiers, allowing driver amplifier operation
from both positive and negative rails. In this way, the amplifier
can be biased at ground (0 volts) potential, generating no
significant DC voltage across the headphone load (the headphones
speakers).
[0025] FIG. 4 illustrates a headphone amplifier circuit 45
according to the present invention. The headphone amplifier circuit
45 includes a first amplifier 46 driving the left headphone, a
second amplifier 48 driving the right headphone, each amplifier
coupled to its respective headphone load 10 via a connecting lead
50 and 52 respectively, and a charge pump 54. The headphones
represented by the headphone load 10 are connected to a common
ground 57. As shown in FIG. 4, instead of a third amplifier 40
shown in PRIOR ART FIG. 3 a charge pump circuitry 54 is used.
[0026] The term "charge pump" refers to a type of DC voltage to
voltage converter that uses capacitors and in an alternative
embodiment inductors to store and transfer energy. One type of
charge pump (also referred to as switched-capacitor converters)
includes a switch/diode network that charges and discharges one or
more capacitors.
[0027] Alternatively, in implementing the present invention, a DC
voltage to voltage converter may be used that includes an
inductor.
[0028] The charge pump circuitry of the present invention generates
a negative voltage rail--VDD with respect to ground, powering the
output amplifiers and allowing driver amplifier operation from both
positive and negative rails. Providing a negative voltage rail with
respect to ground allows for the headphone amplifiers to be biased
at ground voltage, allowing for the incoming signals to be
amplified without clipping. As shown in FIG. 4, the two headphone
amplifiers 46 and 48 have their positive power terminal connected
to VDD the positive voltage supply, and VSS which is approximately
equal to the negative value of VDD with respect to ground. This
arrangement allows for the output terminal of both amplifiers 46
and 48 to be biased to ground, resulting in no significant DC
voltage across the headphones and allowing the elimination of the
large DC coupling capacitors 40 and 42 as shown in PRIOR ART FIG.
2.
[0029] Returning to FIG. 4, each of the headphone amplifiers 46 and
48 has one lead of its supply voltage terminal connected to the
positive voltage rail VDD and another lead of its supply voltage
terminal connected to the output 56 of the charge pump circuitry 54
supplying a negative voltage VSS equal to -VDD.
[0030] The headphone amplifier circuit 45 allows for the headphone
10 to be biased at zero volts, operating between VDD and -VDD which
in turn allows for the leads 50 and 52 of the respective headphone
amplifiers 46 and 48 to directly couple the headphone speakers 10
to the headphone amplifiers 46 and 48 without the need for any DC
coupling capacitors in series.
[0031] FIG. 5 illustrates one embodiment of the headphone amplifier
system of the present invention in a circuit. The headphone
amplifier system 45 includes a left headphone amplifier 46, a right
headphone amplifier 48, a charge pump 54, and external capacitors
C1 and C2. As shown in FIG. 5, in one embodiment of the present
invention, the charge pump circuitry 54 and the power amplifiers 46
and 48 are implemented on a single integrated circuit (IC) chip 45.
In this example, the charge pump 54 operation requires two small
external capacitors C1 and C2. C1 is a called a "flying capacitor"
and C2 is a "reservoir capacitor". The size of these two external
capacitors are in the single digit micro Farad (.mu.F) range as
compared to the DC coupling capacitors of the prior art which are
in the several hundred .mu.F range.
[0032] FIG. 6 is an illustration of an alternative embodiment of a
headphone amplifier system according to the present invention. As
shown in FIG. 6, the headphone driver circuit 58 includes a first
amplifier 60, a second amplifier 62, a switching unit 64, an
external inductor L1 and an external capacitor C2. The inventive
teachings of the present invention may further be implemented using
an inductor based DC voltage to voltage converter. In one
embodiment, the headphone driver circuit 58 may be implemented
using discrete circuit components. In an alternative embodiment, an
onboard inductor L1 may be used in conjunction with an integrated
circuit that includes an integrated switching system as well as
power amplifiers for driving the headphones. In the embodiment of
FIG. 6, an external inductor L1 is used in conjunction with an
external capacitor C.sub.1 to convert a positive power supply
voltage to a substantially equal but negative voltage supply. A
switching unit 64 configures the circuit for each charge and
discharge cycle. The headphone amplifiers 60 and 62 may be directly
coupled to and drive their respective headphones without the need
for DC coupling capacitors since the headphones are biased to
ground and operate between VDD and -VDD, allowing for a complete
incoming signal representation without any clipping.
[0033] FIG. 7 is illustrates a simple capacitor based, IC charge
pump circuitry 66. The simple capacitor based IC charge pump
circuitry 66 includes a pair of amplifier/inverters 68 and 70, an
oscillator 72, a pair of switches 74 and 76, and a pair of external
capacitors C1 and C2.
[0034] In the simple capacitor based IC charge pump circuitry 66,
the switch network 74 and 76 toggles between charge and discharge
states. An oscillator (OSC) 72 controls the two switches (74 and
76) that alternately charge a flying capacitor (C1) from an input
voltage supplied by the amplifier 68 and 70, and discharge the
flying capacitor (C1) into an output capacitor (C2). The voltage
thus produced across the output capacitor C2 may be output as the
output voltage (VOUT). Typically, the oscillator 72, the switches
74 and 76, and still other controls are all commonly contained in a
single integrated circuit (IC).
[0035] The simple capacitor based IC charge pump circuitry 66 is of
the step-up type, and it operates by stacking the potential of the
charge in the flying capacitor C1 onto the potential of the input,
and then charging the output capacitor C2 with this. The optimal
result of this is an output voltage VOUT which is double that of
the input voltage.
[0036] Those skilled in the electronic arts will readily appreciate
that switched connections to the flying capacitor can be changed to
simply shift charge from the input to the output, rather than to
stack it as above. One very common type of step-down charge pump
operates in this way, but further includes an appreciable
resistance in the charge path to the flying capacitor. The
resistance intentionally introduces a delay in the charging of the
flying capacitor, and appropriate control of the oscillator is then
used to switch the charge before it is able to reach the full input
voltage potential. This type of charge pump may accordingly
transfer charge quanta having only one-half, two-thirds, etc. of
the input voltage, and thereby produce an output voltage which is
correspondingly lower than the input voltage. This type of
step-down charge pump is probably overwhelmingly the most common
today, but it is not the only type possible. Alternative circuit
arrangements allow for the generation of an output voltage VOUT
which is equal to some negative quanta of the input voltage.
[0037] FIG. 8 is illustrates a simple capacitor based discrete
charge pump circuitry. The simple capacitor based discrete charge
pump circuitry 78 includes an amplifier 80, a pair of capacitors C1
and C2, a pair of diodes or switches D1 and D2 and includes an
input signal or external clock 82. In the capacitor based discrete
charge pump circuit 78, the basic charge pump circuit is
implemented in a discrete component circuit as shown in FIG. 8. The
amplifier 80 charges a flying capacitor C1. The flying capacitor C1
shuttles charge across a diode D2 and diode D1. A reservoir
capacitor C2 holds the charge and filters the output voltage VOUT.
The external clock signal along with the two diodes D1 and D2
control the cycle and direction of the charge and discharge
signals.
[0038] The foregoing examples illustrate certain exemplary
embodiments of the invention from which other embodiments,
variations, and modifications will be apparent to those skilled in
the art. The invention should therefore not be limited to the
particular embodiments discussed above, but rather is defined by
the following claims.
* * * * *